III.

Types of Radar

All radar systems send out electromagnetic radiation in radio or microwave frequencies and use echoes of that radiation to detect objects, but different systems use different methods of emitting and receiving radiation. Pulse radar sends out short bursts of radiation. Continuous wave radar sends out a constant signal. Synthetic aperture radar and phased-array radar have special ways of positioning and pointing the antennas that improve resolution and accuracy. Secondary radar detects radar signals that targets send out, instead of detecting echoes of radiation.

A.

Simple Pulse Radar

Simple pulse radar is the simplest type of radar. In this system, the transmitter sends out short pulses of radio frequency energy. Between pulses, the radar receiver detects echoes of radiation that objects reflect. Most pulse radar antennas rotate to scan a wide area. Simple pulse radar requires precise timing circuits in the duplexer to prevent the transmitter from transmitting while the receiver is acquiring a signal from the antenna, and to keep the receiver from trying to read a signal from the antenna while the transmitter is operating. Pulse radar is good at locating an object, but it is not very accurate at measuring an object’s speed.

B.

Continuous Wave Radar

Continuous-wave (CW) radar systems transmit a constant radar signal. The transmission is continuous, so, except in systems with very low power, the receiver cannot use the same antenna as the transmitter because the radar emissions would interfere with the echoes that the receiver detects. CW systems can distinguish between stationary clutter and moving targets by analyzing the Doppler shift of the signals, without having to use the precise timing circuits that separates the signal from the return in pulse radar. Continuous wave radar systems are excellent at measuring the speed and direction of an object, but they are not as accurate as pulse radar at measuring an object’s position. Some systems combine pulse and CW radar to achieve both good range and velocity resolution. Such systems are called Pulse-Doppler radar systems.

C.

Synthetic Aperture Radar

Synthetic aperture radar (SAR) tracks targets on the ground from the air. The name comes from the fact that the system uses the movement of the airplane or satellite carrying it to make the antenna seem much larger than it actually is. The ability of radar to distinguish between two closely spaced objects depends on the width of the beam that the antenna sends out. The narrower the beam is, the better its resolution. Getting a narrow beam requires a big antenna. A SAR system is limited to a relatively small antenna with a wide beam because it must fit on an aircraft or satellite. SAR systems are called synthetic aperture, however, because the antenna appears to be bigger than it really is. This is because the moving aircraft or satellite allows the SAR system to repeatedly take measurements from different positions. The receiver processes these signals to make it seem as though they came from a large stationary antenna instead of a small moving one. Synthetic aperture radar resolution can be high enough to pick out individual objects as small as automobiles.

Typically, an aircraft or satellite equipped with SAR flies past the target object. In inverse synthetic aperture radar, the target moves past the radar antenna. Inverse SAR can give results as good as normal SAR.

D.

Phased-Array Radar

Most radar systems use a single large antenna that stays in one place, but can rotate on a base to change the direction of the radar beam. A phased-array radar antenna actually comprises many small separate antennas, each of which can be rotated. The system combines the signals gathered from all the small antennas. The receiver can change the way it combines the signals from the antennas to change the direction of the beam. A huge phased-array radar antenna can change its beam direction electronically many times faster than any mechanical radar system can.

E.

Secondary Radar

A radar system that sends out radar signals and reads the echoes that bounce back is a primary radar system. Secondary radar systems read coded radar signals that the target emits in response to signals received, instead of signals that the target reflects. Air traffic control depends heavily on the use of secondary radar. Aircraft carry small radar transmitters called beacons or transponders. Receivers at the air traffic control tower search for signals from the transponders. The transponder signals not only tell controllers the location of the aircraft, but can also carry encoded information about the target. For example, the signal may contain a code that indicates whether the aircraft is an ally, or it may contain encoded information from the aircraft’s altimeter (altitude indicator).